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Ontologies and engineering analysis

Ontologies and engineering analysis. David Leal Ontology Summit 2012 2 nd February 2012. What is engineering analysis?. Analysts look at the physics systems engineers – want something to do X designers – propose a way of doing X analysts – predict whether or not it will do X

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Ontologies and engineering analysis

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  1. Ontologies and engineering analysis David Leal Ontology Summit 2012 2nd February 2012

  2. What is engineering analysis? • Analysts look at the physics • systems engineers – want something to do X • designers – propose a way of doing X • analysts – predict whether or not it will do X • There is a design analysis loop • design optimisation is part of analysis • Certification is increasingly based on analysis • there are many things that are to expensive to make and break • maybe the demarcation line between what analysts do and what systems engineers do is whether or not physical laws are involved

  3. e.g. crash test simulation • Non-linear geometry, non-linear material behaviour, fluid flow, contact • Decisions about the level of idealisation

  4. Distinctive problems of engineering analysis • Lots of data • gigabytes of data in a single analysis • terabytes within a sequence of analyses for a particular objective • Safety critical • you may be asserting that a product will not break in an event that you cannot replicate in a test rig • some accidents you don t want to replicate • replicating 50 years of life takes a long time • You get asked “how do you know the answers are right” • Ultimately there is an audit trail back to tests • material tests • validation of analysis methodologies

  5. Engineering analysis is a “cottage industry” • Much of it is not routine • you do not necessarily know the analysis steps you will need to carry out before you start • Done by small teams of opinionated people who do not take kindly to PLM (Product Lifecycle Management) systems • a wide range of different disciplines – fatigue, thermal, fluid dynamics, high strain rates, creep, radiation • Work can be subcontracted • analyses of components may be carried out to OEM requirement by the component supplier • Standardisation of analysis data has not taken off • data is much more complicated than geometry • much of the interesting information is about the processes

  6. Engineering analysis is a “cottage industry” • Much of it is not routine • you do not necessarily know the analysis steps you will need to carry out before you start • Done by small teams of opinionated people who do not take kindly to PLM (Product Lifecycle Management) systems • a wide range of different disciplines – fatigue, thermal, fluid dynamics, high strain rates, creep, radiation • Work can be subcontracted • analyses of components may be carried out to OEM requirement by the component supplier • Standardisation of analysis data has not taken off • data is much more complicated than geometry • much of the interesting information is about the processes

  7. Lots of activities, lots of players

  8. International Association for the engineering analysis community • NAFEMS North American Work Session on the Management of Simulation Data "Take Control of Your Analysis and Simulation Data", 27th September 2007, Troy, Michigan (USA). • This session lead to the formation of the North America based NAFEMS Simulation Data Management Working Group. • NAFEMS European Conference on “Simulation Process and Data Management” (SDM), 15th and 16th November 2011, Munich, Germany.

  9. Problems • An engineering analysis ends with: • a text analysis report containing conclusions • some pretty pictures in the report • terabytes of data scattered here and there across servers, which theoretically justify the conclusions • What data is archived with the report? • How do you check the quality of the analysis process? • Hw do you do another analysis of the same component? • often you start again from the product geometry in the PLM system • Has anybody ever done a similar analysis before? • who was it, can the do it again, how long did it take? • did they get the right answer?

  10. Doing better is not difficult • The big files are 99.99% “images” of fields, and 0.01% semantics • Inside the files there are scraps of text that identify parts, features, materials, states, etc. • Inside the files there is limited information about, when, who, and what software (but nothing about why the file was created) • Create a ontology for analysis • parts, features, materials, states, etc. • analysis is 4D • fields are objects • Make the semantics inside the files visible as RDF • the big files are mostly descriptions of the fields • Record the analysis activities • the files are inputs and outputs

  11. Metrics • Quality metrics • mesh shapes, field discontinuities, etc. • Ranges of values in fields • are displacements consistent with a geometrically linear analysis? • are stresses consistent with a linear elastic analysis? • An ontology of metrics will enable them to be recorded • metrics become annotation of the files, and are then readily accessible

  12. Decisions • Decisions are based on statements not “images” • e.g. the maximum surface stress on a weld • e.g. the limit state load • the statements should be explicit and linked to the data files from which they are derived • Decisions are activities • analysis involves many decisions • that a mesh is good enough • that a boundary can be regarded as rigid • that the temperature difference across this wall can’t be more that X • record the analysis decision as a statement • record the activity of making the decision • who was responsible and when

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